Section 2. Electrical Theory

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SECTION 2 – ELECTRICAL THEORY
SECTION 2
1.
Introduction .......................................................................................................... 3
2.
What is Electricity? ............................................................................................. 3
Flow of electrons ................................................................................................... 4
Conductors .............................................................................................................. 5
Insulators.................................................................................................................. 6
Electric circuit ......................................................................................................... 6
Definitions and units............................................................................................ 6
Difference between voltage and current ..................................................... 6
Electrical resistance .............................................................................................. 7
Impedance............................................................................................................... 7
Inductance............................................................................................................... 7
Capacitance............................................................................................................. 8
3.
Ohm’s Law .............................................................................................................. 9
Examples of the use of Ohm’s law .................................................................10
4.
Power ......................................................................................................................11
Unit of power ........................................................................................................12
5.
ELECTRICAL THEORY
ELECTRICAL THEORY
Energy ....................................................................................................................13
Unit of energy.......................................................................................................14
6.
Voltage Drop .......................................................................................................14
7.
Current Systems ................................................................................................16
Direct currents......................................................................................................16
Alternating current .............................................................................................17
Advantage of a.c. for distribution..................................................................18
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8.
Voltage Values....................................................................................................19
Standard line voltages.......................................................................................20
Voltage between live conductors and voltage to neutral....................20
9.
Voltage Systems ................................................................................................21
High voltage overhead systems ....................................................................21
High voltage single-phase system................................................................21
High voltage three-phase system .................................................................22
Phase sequence ...................................................................................................22
Low voltage single-phase 2-wire overhead system ...............................23
Low voltage single-phase 3-wire system ...................................................23
Low voltage three-phase 4-wire system.....................................................24
High voltage single-wire earth return (SWER) system...........................25
10.
The Neutral Conductor...................................................................................26
The multiple-earthed neutral system ..........................................................27
Active-neutral connection ...............................................................................27
TRANSFORMERS ..............................................................................................................28
11.
Elementary Principles of Transformers ..................................................28
12.
Transformer Components ............................................................................30
Tank ..........................................................................................................................30
Bushings .................................................................................................................30
Iron core .................................................................................................................30
Windings and connections. .............................................................................31
Star connections..................................................................................................31
Delta connections ...............................................................................................32
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SECTION 2 – ELECTRICAL THEORY
It is important electrical workers have a good working knowledge of the
principles and theory of electricity so that they can work safely on electric
lines and associated equipment. This is especially so because electricity
cannot be seen and is only evident from the effects that can be experienced,
(for example, light, heat and force).
Unfortunately this increases the risk of harm to people working on or using
electric lines or associated equipment. Electrical workers must use their
training in electrical principles and theory to anticipate how electricity may
flow and to ensure they work safely without causing harm to themselves or
others.
2. WHAT IS ELECTRICITY?
Electricity may be explained by means of the “electron theory”.
In nature, all substances can be grouped into two classes, compounds and
elements. Compounds are combinations of elements in definite proportions.
For example ordinary water consists of two parts hydrogen combined with
one part oxygen, while common salt consists of one part sodium combined
with one part chlorine. The substances hydrogen, oxygen, sodium and
chlorine are known as “elements”. If a small amount of any element is divided
into smaller and smaller parts, eventually a very small amount known as an
“atom” is obtained.
The “electron theory” assumes that these atoms are made up of smaller
particles, electrical in nature, called “protons”, “electrons” and “neutrons”.
A proton is a positively charged particle.
ELECTRICAL THEORY
1. INTRODUCTION
An electron is a negatively charged particle, much lighter in weight than the
proton.
A neutron is about the same weight as the proton but has no charge – it may
be a combination of a proton and an electron.
The protons and neutrons form the nucleus of the atom and the lighter
electrons are imagined to revolve around this nucleus much the same as the
planets revolve around the sun.
In all normal materials, there are as many electrons as protons in the atom.
The atom therefore, shows no electric charge. Figure 1 shows an atom of
hydrogen with one electron and one proton while Figure 2 shows an atom
of helium with two electrons, two protons and two neutrons.
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In materials containing more complex compounds (some may have atoms
with as many as 92 electrons and 92 protons and 146 neutrons) the electrons
are presumed to rotate in orbits of different diameters. When there are only
a few electrons in the outer orbits they are considered to be able to leave the
atom fairly easily. These “free electrons” may then be captured by another
atom that may also have lost an electron.
This action takes place more readily in metals such as copper, aluminium or
steel.
Electron
+ Proton
Figure 1. Hydrogen atom
Electron
Electron
Nucleus
+
+
Neutron
Proton
Figure 2. Helium atom
Flow of electrons
Under certain conditions “free electrons” can be caused to travel from atom
to atom in a definite direction. For example, when a piece of copper wire has
its ends connected to the positive and negative poles of a battery a definite
drift of electrons will take place towards the positive pole of the battery, (see
Figure 3).
The drift of electrons in a definite direction constitutes an “electric current”
and if the number of electrons taking part is great enough, the current can
be detected by suitable means. This theory is used mostly in the application
of electronics, (semi-conductors, diodes etc).
However, owing to certain conventions adapted in the early days of research,
the actual current (conventional current flow) is assumed to flow from the
positive terminal and through the conductor to the negative terminal of the
battery, that is, in the opposite direction to the drift of electrons.
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Conventional Current
Resistance
Electron flow
+
E.M.F.
Battery
Load
Electron flow
Resistance
Conventional Current
-
Figure 3. Conventional current flow compared with electron flow in an electrical circuit
The “force”, as it might be termed, supplied by the battery, that causes this
drift of electrons is called an “electromotive force” (E.M.F) or “voltage”.
It is important to note that the battery has the voltage or force available
without any current flowing, as shown in Figure 4. The voltage available is then
referred to as the voltage on an open circuit and has been labelled E.M.F.
+
E.M.F.
Open Circuit
-
ELECTRICAL THEORY
CONDUCTOR
Figure 4. Open circuit
Conductors
Substances such as copper, aluminium and steel, in which the electrons
readily move from atom to atom, are known as “good conductors”.
Other examples are gold, silver and platinum. Silver is a better conductor
than copper, copper better than aluminium and aluminium better than
steel.
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Insulators
In some materials the electrons are very strongly attached to their atoms
and require a very considerable force to dislodge them. Such substances
are considered very poor conductors of electricity and are known as
“insulators”. Examples are porcelain, rubber, glass, dry wood, and the various
types of plastic coverings in use today such as polyvinyl chloride (PVC) and
polyethylene.
In the best insulators, breakdown of the material takes place before any
appreciable current can flow. Good insulators are therefore used to confine
the flow of current to its desired path. Typical examples are the insulators
used on crossarms to support conductors. Practically no current can flow
from the conductor to the crossarm.
Electric circuit
An “electric circuit” is the complete path that the electric current follows
from its source of supply through the electric line conductor to the electrical
installation or equipment that requires electricity and then back to its
source.
Definitions and units
A simple electronic circuit as shown in Figure 3 has:
a. Electromotive force, (E.M.F), voltage, or pressure, being that
force that causes the current to flow through the electric circuit.
The unit of E.M.F is the volt.
b. Current, being the rate at which electrons flow (or “drift”) in the
circuit. The unit of current is the ampere.
c. Resistance, being the measure of the opposition offered to the
flow of the current by the material of the circuit. The unit of
resistance is the ohm.
These units are so related that an E.M.F of one volt causes a current of one
amp to flow in a circuit of one ohm resistance.
Difference between voltage and current
It is important to distinguish between voltage and current and also to realise
that voltage can exist without a flow of current.
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To produce a flow of current two conditions are necessary. There must first
be available an electrical pressure or, as it is technically called, a voltage or
potential difference.
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SECTION 2 – ELECTRICAL THEORY
For example, when a switch that controls a lamp is open, or set to the “off ”
position there is a voltage across the switch terminals. But because there is
a break in the circuit (the switch being open), there is no flow of current and
the lamp does not glow. As soon as the switch is closed, or set to the “on”
position, the circuit is completed allowing the current to flow and the lamp
glows.
In this case, although there is a voltage present there is no flow of current as
long as the switch remains open. The closing of the switch completes the
necessary circuit and then the current flows.
Failure to distinguish between voltage and current and understand the
condition needed for current to flow has led to a number of accidents that
have harmed electrical workers and the public.
Electrical resistance
An E.M.F. must be applied to maintain a steady flow of current in a circuit.
This indicates that there must be some opposition to the flow of current and
this opposition is known as “resistance”.
Under steady voltage conditions, if more resistance is offered, less current
flows. On the other hand if less resistance is offered with the same voltage
applied, more current will flow. The electrical symbol for resistance is Ω.
Impedance
Impedance is the total opposition to the flow of current in a circuit and
comprises three elements – inductance, capacitance and resistance.
ELECTRICAL THEORY
In addition to the voltage there must be a continuous or complete electric
circuit provided for the current to flow through.
Inductance
When current flows in an electric circuit, a magnetic field is set up around
the conductor. In some cases this will affect the behaviour of current in the
circuit or induce a voltage in a conductor that passes through the magnetic
field. The property that causes these effects is known as inductance.
Typical examples where electrical workers may see the effect of inductance
are:
a.
In the operation of a transformer.
b.
When voltage is induced in a de-energised line that runs
parallel to, or across, a live line.
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A magnetic field stores energy that builds up due to current flow in an
electric circuit. When the magnetic field strength changes or collapses, any
energy stored is released back into those conductors that pass through the
magnetic field. Should this occur, a voltage is induced into these conductors
that can present a hazard to electrical workers or equipment.
The properties of magnetic field and inductance are also put to good use
in an electric circuit. An example is described under transformers in this
section.
Capacitance
When two conductive materials are separated by an insulation material
and connected to a voltage source, the circuit builds up an electric charge
between the conductors. This charge will be maintained until it is discharged.
The property that causes this effect is know as capacitance.
Typical examples of capacitance are:
a.
Capacitor devices in street light control circuits and,
b.
The charge that is stored in an electric cable after it has been
de-energised.
Unlike inductance, the energy stored in the electric charge across a capacitor
is not released when the circuit current is removed. Some capacitors can
hold their charge of electricity for a long time. For this reason, steps must
be taken to discharge any electrical charge before beginning work on
equipment (e.g. cables).
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In 1825, Dr Ohm experimented with the flow of electric current and found
that there was a simple relationship between voltage, current and resistance.
The relationship is known as “Ohm’s law” and is one of the most useful and
important laws in the theory of electricity.
Ohm’s law is that, if one volt is applied to a circuit with a resistance of one
ohm, then one ampere of current will flow.
It is expressed as:
TABLE 1
Electrical Quantity
Unit
Relationship
Current (I) =
Ampere
Voltage ÷ Resistance or E ÷ R
Resistance (R) =
Ohm
Voltage ÷ Current or E ÷ I
Voltage (E) or (V) =
Volt
Current x Resistance or I x R
A method of remembering this law is outlined in Figure 5.
E
I
(A)
R
(Ω)
ELECTRICAL THEORY
3. OHM’S LAW
Figure 5. Representation of Ohm’s law
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Examples of the use of Ohm’s law
The following are simple applications of Ohm’s law.
Example 1
The resistance of conductors in a circuit is 4 ohms. The resistance of a heater
in a circuit is 20 ohms. If the voltage of supply is 240 V what current would
flow in the circuit?
Resistance of conductors = 4 ohms
Resistance of heater = 20 ohms
The total resistance (R) = 4 + 20 = 24 ohms
Voltage of supply (V) = 240 V
To find the current using Ohm’s law
I = V/R
= 240 / 20 = 10 amps
Figure 6 shows the example set out in a diagram. (In solving electrical
problems like this, setting the information out in a diagram often suggests
the methods to use. The starting point of this diagram would be the supply,
then the conductors connecting the heater to the supply).
Conductor Resistance (R1)=4 ohms
+
R1
E.M.F.
R2
240V
-
E
Current, I = – amperes
R
Figure 6. Example 1 set out in a diagram
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Heater
Resistance
R2 = 20 ohms
SECTION 2 – ELECTRICAL THEORY
What voltage would cause a current of 20 amperes to flow in a circuit of 12
ohms resistance?
I = 20 amperes
R = 12 ohms
By Ohm’s law
V
=
IxR
=
20 x 12
=
240 volts
4. POWER
When an electric motor, lamp or other appliance is connected to a supply of
electricity, a voltage is applied across the terminals of the appliance and a
current flows. This enables:
a.
The motor to run and do work in driving machinery;
b.
The lamp to light the room; and
c.
The radiator element to become cherry red and heat the
room.
In fact, the voltage and the current act together to do useful work.
Power is the rate at which work is done. For example, the motor in a) above
drives a water pump that fills a container with water in 2 minutes. If the
same amount of water is to be pumped in 1 minute, it is necessary to double
the power output of the motor as twice as much work has to be done to
pump the water.
ELECTRICAL THEORY
Example 2
In mechanical terms, power is expressed as watts, (W); this is also the unit
of electrical power. For example, car engines have their outputs expressed
in kilowatts (kW, or thousands of watts), e.g. a 30kW engine’s power is
equivalent to 30,000 watts.
The usual bar-type domestic radiator is rated at 1,000 watts per bar, so the
customer knows that if the radiator is connected to a power outlet of 240V
supply, the radiator will deliver 1,000 watts of heat.
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Unit of power
The unit of power is the watt and one watt is the power being used where a
voltage of one volt causes a current flow of one ampere.
In other words:
Power (P)
or P
=
Volts x Amperes
=
Watts (W)
=
ExI
Now referring to Ohm’s law:
Since
E
=
IxR
P
=
E x I then substituting (I x R) in place of E
P
=
IxIxR
P
=
I2 R
The symbol or index “2” means that current is squared or in other words is
multiplied by itself once.
The main point to remember is that P = I2 R
=
W
Power (or watts) used over a period produces heat in conductors or loads so
that wherever voltage and current are combined to produce power, heat is
produced in some form or other. Examples are:
a.
The lamp becomes too hot to handle
b.
The frame of the electric motor becomes warm
The heat is produced because the circuit and electrical equipment will also
have resistance that has to be overcome by the current flow required to do
work in an electric circuit.
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Energy is the measure of capacity to do work.
To obtain a clear picture of the meaning of energy, assume that two people
are each digging a hole of the same size.
One person is big and muscular, but slow in movement; the other person is
small, not so muscular but is quick in movement. The larger person uses a
large shovel and digs slowly, while the smaller one uses a shovel half the size
of the other but shovels twice as fast.
They both dig holes of the same size in the same time and they both have
expended the same energy to do the same job.
The larger person puts twice the force into moving but moves half as fast the
smaller person.
In both cases:
Energy
=
Force x Speed x Time
Energy
=
Power x Time (actual shovelling time)
In electrical terms:
Energy
=
Power x Time
=
Watts x Time
=
Watt-hours
Example 3
ELECTRICAL THEORY
5. ENERGY
A 100 watt lamp burning for 10 hours would expend 100 x 10 = 1,000 watthours of energy.
Example 4
A motor takes 500 watts to drive a drilling machine and runs on this load for
4 hours.
The energy expended
= power x time
= 500 x 4
= 2,000 watt-hours
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Unit of energy
The amount of electrical energy (electricity) supplied to a customer is
generally measured in terms of the kilowatt-hour (kWh).
The kWh is the energy expended in one hour when the power being drawn
is one kilowatt. It is equal to 1,000 watt-hours.
Although this unit is known as the kilowatt-hour (kWh), it is frequently
referred to simply as the “unit”. This unit is well known to those who pay
electricity accounts and in order to measure these units, meters called
“kilowatt-hour meters” or “kWh meters” are installed.
6. VOLTAGE DROP
When current flows along the conductors of an overhead electric line, it flows
against resistance. The total resistance offered is made up of two parts:
The resistance offered by the connected load, that is the lamps, motors etc.
and
a.
The resistance of the conductors themselves.
b.
Conductor resistance is important because it constrains the capacity
of an electric line. The effect of the resistance is to reduce the voltage
available to do useful work.
Example 5
Referring to Ohm’s law again, E = I x R
If the resistance of an overhead conductor in its entire circuit is 2 ohms and
a current of 10 amperes is flowing, then the voltage necessary to cause this
current to flow against the resistance of the conductors alone will be 10 x 2
= 20 volts; this is the voltage drop in the conductor.
If at the supply end the voltage is 240 volts, then the voltage available to
the customer whose appliances are causing 10 amperes to flow will be (240
– 20) = 220 volts.
The need for voltage to provide the force for the current to overcome
resistance in the conductors from the supply to the load (and return to the
source) has reduced the voltage available for the customer’s appliance.
If the demand for electricity increased from 10 to 20 amperes, the voltage
drop in the conductors would increase from 20 to 40 volts. The voltage drop
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In addition to the undesirable effects of excessive voltage drop (eg.
fluctuation seen in filament lamps and on television screens), the resistance
of the conductors will determine the power lost in the conductors, because
work has to be done to overcome the resistance.
In example 5 using the formula
P = I2 R
where
P = power in watts
I = current in amps
R = resistance in ohms of the conductors
then
P = 10 x 10 x 2 = 200 watts
This power loss for five hours would expend one unit of energy.
watts x hours (Wh) = 200 x 5
= 1,000 watts
= 1kWh (or unit)
It can also be shown that, for the same material and current:
a.
Voltage drop increases with the length of the conductor.
b.
Voltage drop decreases with the increase in cross-section
(thickness) of the conductor.
Since voltage drop is a product of current and resistance, it is essential that
the resistance of electric lines is kept to a minimum to obtain the rated value
of voltage at the receiving end of a line. The number of joints in a line should
be kept down to an absolute minimum and the joints themselves must be
clean and well made to have as low a resistance as possible, as every joint or
connection introduces some amount of resistance to the flow of current.
ELECTRICAL THEORY
would reduce the voltage available for the customers appliances to 200 volts.
At this level the operation of many appliances will be adversely affected.
When current passes through a resistance, however small, some voltage
drop is experienced; these small voltage drops may add up to an appreciable
amount where there are a number of joints or any badly made joints.
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7. CURRENT SYSTEMS
Electric currents are of three classes: (a) direct, (b) alternating, and (c)
pulsating. Distribution & Transmission electrical workers are mainly
concerned with alternating currents.
Pulsating currents do not come within the scope of this Handbook, and will
not be addressed.
Direct currents
A direct current (d.c.) system is one in which current flows in one direction
in the conductors of that system. An everyday example is the car battery,
which has two terminals, one positive (+) and the other negative (-).
The accepted convention is that the current flows from the positive terminal
to the external circuit and returns to the negative terminal.
High voltage transmission of electricity by direct current has been developed
over recent years. In general, however, d.c. distribution is limited to use in:
a.
Tramway and traction systems with a voltage of usually 600V;
b. Railway d.c. traction systems with a voltage of 1.5kV between
rail and overhead collector wire;
c.
Lifts, printing presses and various machines where smooth
speed control is desirable;
d. Electroplating; and
e.
Battery charging.
Usually d.c. systems are of 2-wire or 3-wire types. In a 2-wire system one wire
is positive and the other negative. The difference in potential for tramways
is 500V with the rail negative and in the d.c. railway system the difference in
potential is 1.5kV, again with the rail negative.
In a 3-wire system the standard voltages are 460 and 230V.
There are three wires, one being at 230V positive (or + 230 volts potential),
the second 230V negative (or – 230 volts potential), with the third called the
“common” or neutral being at zero potential (see Figure 7).
Supply at 230V is taken from the “outer” (or positive) and the common
conductors, or from “inner” (or negative) and the common conductors.
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240 V + outer
240 V 480V
Common or Neutral
240 V
240 V - inner
Balancing
coil
Figure 7. Potential in a 3-wire system
Energy for motors at 480V is taken from the outer and the inner conductors.
Alternating current
An alternating current (a.c.) flows in an electrical circuit that is energised
with an alternating voltage. This voltage is one that reverses its sense of
direction in a regular manner, and this is caused by the method by which it
is generated.
In simple terms, the generator is a copper coil, which is mounted on a shaft
between opposite poles of a magnet. When the shaft spins, the copper cuts
the magnetic field and a voltage appears at the ends of the coil.
The generator (or alternator) is shown in Figure 8.
As the coil rotates one revolution the voltage follows the variation shown in
Figure 9.
O
1 cycle
Magnetic
field
Copper coil
ELECTRICAL THEORY
D.C. 3-wire
supply
Voltage
+ max
max
Slip rings
S
0.02
Seconds
0
Time
Voltage terminals
- max
Figure 8. Simple a.c. generator
Figure 9. a.c. voltage wave form
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When the coil is at right angles to the magnetic field, it is not cutting the field
and the voltage is zero.
The maximum rate of cutting occurs when the coil is in line with the magnetic
field and there is a maximum voltage output.
From zero to maximum and beyond maximum back to zero occurs in one
half revolution and the voltage rises and falls.
In the next half revolution, the generated voltage is opposite to the first half.
One full revolution of the coil produces one “cycle” of variation.
The number of voltage cycles in one second of time is called the frequency
of the supply, and is given the name Hertz (Hz). The standard frequency in
Australia is 50Hz.
Advantage of a.c. for distribution
Alternating current has an important advantage over direct current in that
the voltage can be changed by transformers to a high value for transmission
over long distances and then reduced at the customer’s point of supply to a
lower level suitable for operating lights, motors and other appliances.
As power = volts x amps, for the same power level to transmitted, a high
voltage can be used so that the current can be kept to a low level thereby
minimising the voltage drop.
Transmission of high power levels therefore requires:
a.
Resistance of the transmission line to be as small as possible;
b.
The transmission line current to be as low as possible.
The first condition cannot always be met, as it needs conductors of large
cross-sectional area. Large conductors are expensive and their great weight
would require strong and costly supports.
On the other hand, the second condition can be met by raising the
transmission line voltage so that high power levels can be transmitted with
relatively small currents. The small currents in turn require relatively small
cross-sectional area, lightweight conductors with correspondingly lighter
supports. Therefore, when high amounts of power levels are involved, it
is general practice to use high transmission voltages and relatively small
currents with correspondingly small voltage drops.
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Transformers are used to provide the high voltages necessary for the
transmission of high power levels over long distances.
In keeping with the value of the transmission line voltage employed, it is
necessary to insulate the conductors against leakage to earth.
8. VOLTAGE VALUES
In the following, “voltage” means the voltage between the conductors.
The standard voltage values used are:
1.
Extra low voltage (ELV) – means any voltage not exceeding 50V a.c. or
120V ripple free d.c.
2.
Low voltage – means any voltage exceeding 50V a.c. or 120V ripple
free d.c. but not exceeding 1kV a.c. or 1.5kV d.c. Thus the normal
voltages of 240V and 415V delivered to most customers are “low
voltage”.
3.
High voltage (HV) – means and voltage exceeding 1kV a.c. or 1.5kV
d.c.
4.
Extra high voltage (EHV) means any voltage exceeding 220kV.
ELECTRICAL THEORY
This condition is much more efficient than if an equivalent power level were
transmitted at low voltage and high current with a relatively high voltage
drop.
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Standard line voltages
The standard line voltages in use are:
240/415V (3 phase)
240/480V (1 phase)
}
Used to supply customers installations
6.6kV
11kV
22kV
12.7kV (SWER)
22kV
}
Used for urban and rural HV distribution
33kV
66kV
}
Used for sub-transmission of larger power levels
in distribution over middle distances1
110kV
220V
330kV
500kV
}
Used for transmission of large power levels over
long distances
1
In some urban areas of Victoria there are pockets of 22kV subtransmission.
Voltage between live conductors and voltage to neutral
The voltage between any two live conductors is often referred to as the “line
voltage”.
The voltage to neutral, often referred to as the
“phase voltage”, is the voltage between any live
conductor and the neutral point or earth of the
system.
Figure 10 shows the line and phase voltages in a
three-phase system. The neutral point is usually
earthed at the supply end (for protection and
safety reasons) and each live conductor is then
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Figure 10. Three-phase system with earthed neutral
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A
Phase
Voltage
Line Voltage
Line Voltage
Phase Voltage
Phase Voltage
C
Line Voltage
E
B
SECTION 2 – ELECTRICAL THEORY
9. VOLTAGE SYSTEMS
High voltage overhead systems
The two systems most commonly used for transmission and distribution
are:
Single-phase
Three-phase
High voltage single-phase system
This system is generally associated with the distribution of low power levels
over relatively short distances. Single-phase systems are generally fed from
a three-phase line.
The single-phase line consists of two conductors, neither directly earthed to
the general mass of earth. In this system there is no neutral conductor (see
Figure 11).
It is usual to have the three-phase system earthed (at the neutral point of
the transformer or generator supplying the system) either solidly or through
some current limiting resistance (for safety and protection purposes). As the
single-phase HV system is part of the three-phase HV system, each phase of
the single-phase system has a definite voltage to earth.
3 phase HV system
For safety reasons alone, it is important to remember that each phase is
alive to earth and that a definite voltage exists between each phase and the
equipment connected to the ground.
A B
ELECTRICAL THEORY
at a definite potential to earth. For instance, in an 11kV three-phase system,
the voltage between any two live conductors gives a line voltage of 11kV
while the voltage between any live conductor and neutral (or earth) gives a
phase voltage of 6.35kV.
Single phase HV system
(single-phase spur)
B
C
C
Figure 11. Three-phase high voltage system with single-phase spur
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SEC2:
21
High voltage three-phase system
This system is widely used for the transmission of high power levels and is
also the standard system used in distribution and reticulation.
It consists of three conductors, each called a “phase”. To standardise the
identification of the phases, they are known as A, B and C phases or red,
white and blue phases respectively.
The voltage in each phase alternates, in a similar manner to the alternating
voltage shown in Figure 9 but one follows the other in regular order (see
Figure 12).
A
Voltage
ELECTRICAL THEORY
SECTION 2 – ELECTRICAL THEORY
B
1
100
C
1
50
Time (secs)
Figure 12. Representation of the three sine waves in a three-phase system
Briefly, phase A reaches its maximum positive value first, then is followed by
phase B, then by phase C and so on. The order in which the phases reach
their peak is called the phase sequence.
Phase sequence
It is essential that the order of phase sequences and the identity of the A,
B and C be known. In the case just cited, the order of phase sequence was
from A to B to C because the voltage in phase B reached its maximum value
after that in phase A and the voltage in phase C reached its maximum value
after that in phase B.
Phase sequence has an important bearing on the direction of rotation of
three-phase a.c. motors, which depend on the phase sequence and the
relative position of the three-phases connected to the motor terminals.
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A reversal in the order of the phase sequence (eg. by interchanging any two
of the three wires connected to its main terminals) will cause the motor to run
in the reverse direction of rotation. For this reason alone, it is important that
electrical workers know what happens if there is an inadvertent change in
the position of the phases supplying a factory in which motors are installed.
VESI Fieldworker Handbook updated 2008
SECTION 2 – ELECTRICAL THEORY
In this system there are two conductors, one generally solidly earthed at
the transformer and known as the “neutral”, while the other is known as the
“live”, “active” or “phase” conductor.
The voltage between phase and neutral is nominally 240V and the
voltage of the phase or active conductor to earth is therefore also 240V
(see Figure 13).
“Live’ phase
240V
to neutral
H.V. single
phase line
240V
to earth
Neutral
0V
E
E
Figure 13. Single-phase 2-wire system
Low voltage single-phase 3-wire system
In certain rural areas, it is often more economical to install a single-phase high
voltage line, saving the cost of the third high voltage phase and to supply
the load by stepping down through a transformer to a 3-wire system. One
conductor is earthed and known as the neutral while the other conductors
are both “actives”. (see Figure 14).
ELECTRICAL THEORY
Low voltage single-phase 2-wire overhead system
“Live’ ” outer
240V
H.V. single
phase line
480V
Neutral
240V
E
“Live” inner
E
SEC2:
Figure 14. Single-phase 3-wire system
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23
ELECTRICAL THEORY
SECTION 2 – ELECTRICAL THEORY
The voltage between either of the actives and the neutral is 240V while the
voltage between the two active conductors is 480V. It is the a.c. equivalent
of the three-wire d.c. system. It facilitates the supply of larger loads or loads
at greater distances from the transformer than the single-phase 2-wire
system.
Half of a domestic 240V load is connected between one active and the
neutral and the other half between the other active and the neutral. This
balances the load on each phase and reduces, if not eliminates, the residual
current in the neutral.
Low voltage three-phase 4-wire system
This system employs four conductors and is widely used in all areas where
it is considered economical to supply large amounts of energy for industrial
and domestic purposes. The system is shown in Figure 15; a, b and c are the
active conductors and n is the neutral which is connected to the “star point”
of the transformer. It is usual for the “star point” to be earthed as shown.
“Live”
A
3-phase
H.V. line
a
“Live”
B
“Live”
C
Neutral
415V
415V
b
240V
415V
240V
c
240V
d
E
Figure 15. Three-phase system with earthed neutral
The standard voltage between actives is 415V, while the voltage between
any one of the actives, (a, b and c respectively) and the neutral is 240V.
The same phase relationship of “phase sequence” exists on the LV as on the
HV side of the transformer, so care must be taken when renewing mains to
avoid upsetting the phase sequence to the supply of motor loads.
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VESI Fieldworker Handbook updated 2008
SECTION 2 – ELECTRICAL THEORY
The power system known as the SWER system uses only one HV conductor
with the earth being used as the return conductor, (see Figure 16). This system
was first developed in New Zealand and is now used in Australia, South Africa
and many other countries. It can have great economic advantages in hilly
areas where the loading is relatively light, where long distances are involved
and where the line can be strung from ridge top to ridge top. Because of the
generally lower impedance of the line to earth circuit, it usually has better
voltage regulation than a conventional single-phase 2-wire circuit.
To restrict noise interference in telecommunications systems, the amount
of earth current allowed to flow in the earth return circuit is limited.
Furthermore, there must be a minimum separation between SWER lines and
any telecommunication lines.
A special transformer is used to isolate the SWER line from the main
distribution line. The SWER line voltage is 12.7kV to earth. The distribution
transformers fitted to the SWER line can be either single-phase 2-wire 240V
supply or single-phase 3-wire 240/480V supply.
Particular attention must be paid to the good earthing of the transformers
on a single-wire line and to the protection of these earth wires from physical
damage.
Single phase spur line
22kV
12.7kV
ELECTRICAL THEORY
High voltage single-wire earth return (SWER) system
N
E
Normal 3 phase
HV line
Secondary supply Secondary supply
240V single
240/480V
phase
single phase
Figure 16. Single wire earth return system
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ELECTRICAL THEORY
SECTION 2 – ELECTRICAL THEORY
10. THE NEUTRAL CONDUCTOR
In a low voltage single-phase 2-wire system, one conductor is earthed
as shown in Figure 13. Both conductors are necessary and the neutral
conductor may carry as much current as the active conductor, depending
on the earth resistance and other factors.
In the case of the three-phase 4-wire system as shown in Figure 15, a different
condition is found. The neutral conductor is necessary to be able to obtain a
240V supply (between any of the three actives and the neutral).
It is found that when each phase is equally loaded, there is no return current
in the neutral conductor. This can be easily demonstrated as shown in
Figure 17. Three 1kW heaters for example are connected as shown, one
on each phase. When heater A for example is switched on, the ammeter
records the current taken by the heater, that is 1000/240 = 4.2 or about 4¼
A. On switching on heater B, the current recorded by the ammeter does not
increase to 8½ as might be expected but remains unchanged. Finally when
heater C is switched on to give a three-phase balanced load, the ammeter
reading falls to zero. If there are equal amounts of current in all of the three
phases, then there will be no neutral current flowing in the neutral. In
practice, the neutral is always required and since, in fact, a perfect balance
is very seldom achieved, there is always some current in it. This current
is usually considerably less than the current in the active conductors and
consequently the size of the neutral can theoretically be smaller than that of
the active conductors. In modern practice, the neutral is often left the same
size as the active conductors to ensure the lowest possible resistance for the
return current.
a
3-phase b
4-wire
c
supply
n
C
Ammeter
Figure 17. Three-phase 4-wire supply
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VESI Fieldworker Handbook updated 2008
B
A 1kW heaters
SECTION 2 – ELECTRICAL THEORY
A good neutral conductor provides a low-resistance path back to the
transformer for out-of-balance currents. If the neutral should be broken
under these conditions, quite a considerable voltage can develop between
the broken ends and, if both ends are held in the hands, a severe shock will
result. Therefore it is as important with the neutral as it is with actives, not to
handle both ends of a broken conductor unless supply has been isolated.
The multiple-earthed neutral system
The multiple-earthed neutral (MEN) system is widely used in Australia.
Under this system, the neutral, in addition to being connected to earth at the
supply end (that is, at the transformer), it is also connected to earth at each
customer’s premises. In addition, it is frequently earthed at other points and
at the ends of distribution lines. From this arises the term “multiple-earthed
neutral”.
Under the system, the neutral is connected to earth at one point only at
each customer’s premises. The metal frames of electrical appliances such
as ranges, motors and so on are separately earthed, the neutral being
kept insulated from the frame of the appliance or apparatus, except at the
switchboard where it is connected to the customer’s main earth.
For further detail on earthing systems, see Subs, Caps & ACR’s.
ELECTRICAL THEORY
For example, with 50mm2 copper active conductors, a 35mm2 copper neutral
is sometimes used. In certain circumstances (for example if one fuse blows),
the current in the neutral can be as great as in the active. Neutral current
can also be large when transformer neutrals are interconnected. For these
reasons, it is usual for the neutral to be the same size as the actives.
Active-neutral connection
It is vital to ensure that in connecting the customer’s premises, that active
and neutral are not reversed. If this happens, the customer’s earth main
should cause the service fuse to blow but, if the customer’s earth is faulty,
broken or of high resistance, there may be insufficient current to blow the
fuse. In this case, all metal connected to the customer’s earthing system, eg.
range, water pipes, becomes alive and extremely dangerous, this situation is
known as a “reverse polarity”.
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TRANSFORMERS
11. ELEMENTARY PRINCIPLES OF TRANSFORMERS
A transformer has three principal parts:
a. An iron core, which provides a continuous magnetic circuit
b. A primary winding, which draws current from the supply circuit
c. A secondary winding, which receives energy by
electromagnetic induction from the primary winding and
delivers it to the secondary circuit
NOTE: The primary winding is always considered to be the winding supplied
by the voltage to be changed, whether it is the higher or lower voltage
winding. The secondary winding is the one supplying the load.
In its most elementary form, a single phase transformer consists of an iron
core with the primary and secondary windings wound on separate limbs of
the core as shown in Figure 18.
Iron core
Secondary
Primary
Iron core
Secondary
Primary
ELECTRICAL THEORY
SECTION 2 – ELECTRICAL THEORY
Figure 18. Iron core and windings
The two windings are quite independent of each other. In practice, part of
each winding would be wound on each limb of the core.
As with any other piece of electrical equipment, the output from the
transformer is equal to the input, less any losses occurring in the transformer.
If losses are ignored, then:
Output (kVA) = Input (kVA)
Where kVA
= (volts x amps) / 1,000 (volt amps)
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SECTION 2 – ELECTRICAL THEORY
(50 x 1000)
Primary current
=
22000
=
2.3 amps approximately
=
(50 x 1000)
and
Secondary current
240
=
208 amps approximately
The high voltage winding can therefore be made of fine wire but the low
voltage winding will be required to be of much heavier wire.
The number of turns and the voltage of either winding are proportional to
one another:
Ep
Es
=
Np
Ns
Where:
Ep is the primary voltage
Es is the secondary voltage
ELECTRICAL THEORY
This means that the higher the voltage, the smaller the current for the same
kVA. For example, if the rating of a single phase transformer is 50kVA, the
primary voltage 22kVA and the secondary voltage 240V, then:
Np is the number of turns on the primary winding
Ns is the number of turns on the secondary winding
Taking the transformer in the previous example, the primary voltage was
22kV and the secondary voltage 240V. If then the secondary winding had 23
turns, the number of turns on the primary winding would require to be:
22000
240
x 23
=
2108 turns
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ELECTRICAL THEORY
SECTION 2 – ELECTRICAL THEORY
12. TRANSFORMER COMPONENTS
Tank
With small distribution transformers, the tank may be quite plain. Heat is
radiated from the sides of the tank or carried away by air movement. In large
transformers, external cooling tubes or fin-type radiators are fitted and the
larger zone substation type transformers may be equipped with separate
radiator banks. Fans may be mounted on radiators to increase the rate of
heat transfer to air, and oil pumps may force circulation of the insulating oil
through the core, windings and radiators where the heat is released to air.
The tank has a tight fitting lid. Others fittings may include a breather or open
or silica-gel type (to keep moisture out of the transformer), oil gauge and an
oil drain/sampling valve near the bottom of the tank and a thermometer
pocket for temperature monitoring purposes. Distribution transformers
with a sealed tank are becoming more common. These transformers do not
breathe to the outside but have an air space above the oil or flexible sides
to permit expansion and contraction of the oil with changing temperatures.
The advantage of this design is that, because there is no air movement into
or out of the tank, the transformer oil is not exposed to contamination by
dirt or moisture laden air.
Smaller transformer tanks may also include termination cubicles either
welded or bolted to the tank to enclose the bushings and house items such
as low voltage fuses.
Hooks or eyes are fitted to the transformer tank so that it may be lifted with
chains or wire slings.
Bushings
The primary and secondary leads have to be brought outside the tank
to permit connection to the electricity supply and the load by means of
porcelain or cast resin bushings. These may be enclosed in an air-spaced
termination cubicle or a cable box or they can be exposed without other
protection. Bushings are brittle and easily broken so care must be taken
when handling any exposed fittings.
Iron core
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The core of a transformer provides the magnetic circuit that permits the
transfer of energy between the primary and secondary windings. The core
is normally manufactured from a special grade, low resistance, steel sheet
cut into laminations and then clamped together to form the core. The
VESI Fieldworker Handbook updated 2008
SECTION 2 – ELECTRICAL THEORY
Air gaps between laminations resist the path of the magnetic circuit and
assembly techniques have been developed so that the laminations on
modern transformers are now assembled with very small air gaps between
lamination butt joints.
Advances in the types of material used for the core and in the methods of
assembly have greatly improved transformer efficiency and reduced the
sizes of the cores required for the same power output.
Windings and connections
Windings around the core can be assembled in a variety of ways. The primary
and secondary windings are efficiently magnetically coupled and have low
electrical impedance. The windings themselves are of either copper or
aluminium and may be either in conventional wire form or long strips of
sheet. Normally the aim is to make the length of wire or strip wound on the
core as short as possible to reduce losses caused by the winding’s resistance.
Star connections
In this method of connection, the “ends” of the windings (shown in the
diagram as 2) are connected together and normally connected to earth (or
Neutral). The remaining ends (shown in the diagram as 1) are then connected
to the phases, a, b, c of a three phase line. The common connection is known
as the “neutral” or star point.
}
Supply Line
Phase I
1
2
ELECTRICAL THEORY
purpose of using laminations is to prevent excessive induced currents (eddy)
circulating in the core and causing heating of the transformer.
PhaseA
I
Phase II
2
1
2
Phase III
PhaseB
II
1
PhaseC
III
Neutral N
ABC
E
(a)
(b)
SEC2:
Figure 19. Star connected 3-phase windings
VESI Fieldworker Handbook updated 2008
31
Delta connections
In this method the connections are made as follows; the end of winding I
(shown in the diagram as 2) is connected to the beginning of winding II and
so on, until the end of winding III is joined to the beginning of winding I. This
connection does not give a neutral connection.
Supply Line
}
ELECTRICAL THEORY
SECTION 2 – ELECTRICAL THEORY
1
Winding I
1
2
Y
R
B
II
Y
II
I
Winding II
Delta
III
B
1
III
Winding III
2
RYB
(a)
(b)
Figure 20. Delta connected 3-phase windings
SEC2:
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I
R
2
VESI Fieldworker Handbook updated 2008
(c)
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